Automatic counting apparatus



ug- 20, 1957 w. D. HOWELL 2,803,405

' AUTOMATIC couNTzNG APPARATUS Filed June 2, 1952 11 Sheqts-Sheet 2 SCALE/P o n? C M or* T/M/NG M. fg/XCI/ O/L c. ouEPP/DE /MPULSE SW! TCH S5 T/ME Co/vnPoL GENE @A709 v BASE U/v/r "I RE Ay l I @HELENE/vri@ L c IN/7" o i .9@ es. 42/ .55/

PRINTER I UNIT J TIME I v /NrE VAL 35 PRI/57E@ f4.5' 50 'F-Lsq E START FS-Ei- E y william D. Haelen ug- 20, 1957 w.D. HOWELL 2,803,405

AUTOMATIC couNTING APPARATUS .med June 2, 1952," 11 sheets-sheet 5 Aug. 2o, 1957 w D HOWELL 2,803,405

AUTOMATIC COUNTING APPARATUS Filed June 2. 1952 11 Sheets-Sheet 4 i PL l I J. sy/va Home I C5 -0/ I loo/EPM S04/VMM; D/sc.

Aug. 20, 1957 w. D. HOWELL 2,803,405

4AuTowuxfrIc COUNTING APPARATUS Y med June 2, 195,2- llshets-sheet 5 ug- 20, 1957 w. D. HOWELL 2,803,405

`AuToA/IATTTC couNTTNG APPARATUS Filed June 2, 1952 11 sheets-sneer e ELE l' PPL-tss ro FEVEE'SE ZwPNrABLE 'Ez/enor William J).v Howell @www Aug. 20, 1957 w. D. HOWELL 2,803,405

AUTOMATIC COUNTING APPARATUS Filed June 2; 1952 l1 Sheets-Sheet 7 www Aug. 20, 1957 w. D. HOWELL 2,303,405

y AUTOMATIC COUNTING APPARATUS Filed June 2, 1952 11 Sheets-Sheet 8 6 F l5 TIP/AL COU/V7' PIP/N TER v RESET COUNTER L2 CLUTCH s O Y F* :LE-Ill william @.WazueZZ Aug. 20, 1957 w./D. HOWELL AUTCMATIC COUNTING APPARATUS 11 Sheets-Sheet. 10

Filed June 2, 1952,"

Y time foreach trial.

3 Figure 1 is a simpliiied block diagram of an arrangement of apparatus in accordance with the invention.

Figure 2 is a chart showing the programming for fully automatic time or countcontrolled operations in apparatus as shown in Figure l,

- Figure 3 is a further simplified block diagramrof an arrangement of apparatus according to the invention,

- Figure 4(a) and Figure 4(b), which together form Figure 4, are a circuit diagram of the base unit shown in Figure 3, 'Y

'Figure 5 is acircuit diagram of the' timing impulse generator, I p

Y Figure 6 s a circuit diagramV of' the override time control,

Figure 7 isa cireuitdiagram for the printer unit,

' Figure 8 is a circuit diagram for the complementer unit,

Figure 9 is a circuit diagram for the recycle unit, Figure 10 is a circuit diagram for the relay unit, Figuregll, is a circuit diagram for the elapsed time control unit, g

Figure 12 is Va chart and table showing times of energizetion of the A. C. lines vshown in Figures 4 to 12.

Figure 13 is a circuit diagram of a preferred arrangement of the Vprinter unit, and

Figure 14 is a simplified block diagram showing an automatic scanning pulse lanalyzer in accordance with the invention. g i

e The block diagram shown in Figure 1 is intended to give lonly a general idea of the arrangement of apparatus according to'gthe invention, more specificV information as to the circuits of the various units and the interconnections between units being given in the other gures of the drawings. As shown in Figurel, apparatus according to the invention comprises a recycle unit 30, which may include the source of pulses to be counted, connected to one ofthe contactsjof a switch 31 so that it can be connected to the input of an electronic sealer 32. The electronic sealer 32 may be ofthe type described in United States Patent No. 2,691,100 issued October 5, 1954, for Electronic Counterfrin the names of N. F.'Moody and W. D. Howell. The input of the sealer 32 is also arranged to be connected through the switch 31 either to an oft-position or to the output connection of a Vsouree33 of regular complementing pulses (referred to belowras the complementer 33). Y The outputofthe sealerV 32 is connected to the circuit jfor controlling the Voperation of the print stamper 34 of Ya time interval printer 35 and Vis also connected `to one vcontact ofjaswitch 36. The other contact ofthe switch 36 is connectedV to the output of a source 37 of regular timing pulses. The switch 36 is arranged to connect either the Voutput ofY the sealer or the output of the source 37 of .timing pulses to the input of a reset counter 38. VThe output of the reset counter is connected to control the operation of the timer motor 39 of the time interval 'printer 435. The voutput of the reset counter 38 is also arranged to control the operation of the'switch 31 as indicated in dotted line in lFigure 1. An override time control` 40 lis also connected to the timer motor 39 and the switch 31 so that Yif,'during count controlled operation, aweek Vsampleoeeupies the apparatus for longer than a predetermined time, the overridetime control eanveonnect the complementer 33 to the scaler-32 and at the same time start the timer motor 39.

. In time controlled operation oftheapparatus shown in Figure l, the reset counter .38 is connected to the source 37 of regular timing pulses through the switch 36, and it isA adjusted so that it will perform its switching functions and reset itself at a count equivalent to the predetermined The recycle unit 30 starts thecount after the source of pulses to be counted is in positionand after the necessaryinternal connectionsin the Yapparatus have been made. The pulses are supplied from the recycle unit 30 through the switch 31 to the input of the sealer 32, Assuming that the sealer 32 is designed to scale down print stamper 34. During time controlled operation the timer motor 39 is disconnected from the print stamper 34 and the printing wheels do not rotate so that a row of zeros is printed each time the print stamper 34 is energized. When the reset counter 38 has received a number of timing pulses equivalent to the predetermined time for the trial, it will operate causing the timer motor 39 to be coupled to the print stamper 34 and the sealer 32 to be connected to the complementer 33. Upon the next output pulsefrom the sealer 32 the print .stamper prints the time during which complementing pulses were supplied to the sealer 32 and the apparatusthen reeycles for the next trial. The following table shows an example cfa printed record for a time controlled operation and provides an explanation of how the record is interpreted:

TABLE l Printed record for Vzzl time controlled operation using a standard time interval printer Y Trial period preset at one minute.

Scaling factor of 1000. Complementing pulses supplied at the rate of 10D/minute. Digits 0f printing wheels 0f print stamper change at tate of 10Q/minute. y(Read up) Trial No. Printed Signieance of YPrinted Record Record 4 0000.00 Vstammentrial-imitating f Y it ls greater than 1,000

06 counts. p wg: 00 }o0unt=2,000.300=1,694. 0001. 65 C01mt=1,000'165=835. 0000.40

`0000.00 Y Y M: 83 eount=6,00040:75060.V 0000.00

Table 1 shows thatin trial No. 1, 5960pulses were produced by the sample under measurement during one minute. Each row of printed digits represents a thousand input pulses to the sealer 32 Vand the last row (the upper one for trial No. ll) shows vthat in order to obtain the iinal output pulse yfrom the sealer 32 the complementer 33 had to supply complementing pulses for .40 minute and, therefore 40 complementing pulses (.40 100, i.e. timex the rate at which complementary pulses are supplied) were received by the sealer. Accordingly .the count of pulses from the sampleV during the trial is 6000-40.,='5,960 pulses, which in more general terms is the number of printed rows'of digits 6) multiplied by the sealing'factor V(1000) minus lthe compliment (.40 '100.);

`For-count controlled operation, the reset counter 38 is connected to the output ofthe Vsealer 32 through the switch 36, and Vit is adjusted so that it Ywill perform its switching operations and reset itself at a count equal to the predetermined count for each trial. The timer motor 39 is coupled Vto the` print'stamper 34 so that each output pulse from the Yscalerr32 will cause the time'fof its occurrence to be printed Vby the Ytime interval printer" Y 35. The recycle unit 30 ystarts the count when .the source of pulses to be countedis in position and after Ythe necessary internal connections theV fapparat'usl'have been made. Pl`heypuls'esfrornthve recycle unit 30 .arelsupplied through the switch 31 Vto the input of the 'sclerr3 2.f .Irf, as-in the ease of the timecontrolledoperation.described above, the sealer 372-,V is `designed to scale .downfin the. ratio of "1000g-1 itwillproduc'e' `anoutputfpulse for each 1000 input pulses. Each output pulse from the'sc'aler A32,

representing 1000 pulses from the recycle unit 30, is fed to the print stamper 34 ofthe time interval printer '35` causing the print stamper 34 toprint the time of its occurrence. At the same time, the reset counter 38 is counting the output pulses of the sealer 32 and, upon the predetermined count for the trial being reached, it performs its switching functions and resets. 'I'he printed record produced by the time interval printer 35 shows the time for the predetermined count and the apparatus automatically recycles for the next trial. As shown in Figure 1, an override time control 40 is provided so that the apparatus will not be occupied with a low counting rate trial for an excessively long time. The overridel time control can be set to operate at a predetermined time after the start of each trial and, upon operation, it causes the print stamper 34 to print the time and simultaneously causes the input of the scaler 32 to be switched to the complementer 33. The next output pulsefrom the Scaler 32 causes the time to be printed, and the apparatus then recycles for the next trial. The following table shows an example of a printed record for a count controlled operation and provides an explanation of how the record is interpreted:

TABLE 2 Complementing pulses supplied at the rate of D/minute. Digits ot printing Wheels of print stamper change at rate of 10G/minute.

(Read up) Trial No. Printed Record Comments -Override time control operated at 15.02

0022.19 -Override time control operated at 15.08

man.

0015.08 Sample count is 1,000(22l9-l508)=289 in 15.08 min.

As indicated by Table 2 the total count in thousands for any given trial is one less than the number of rows of printed digits in the printed record for the trial, and the difference between the two iinal printed times is equal to the complement which must be subtracted from the total count in thousands.

Figure 2 shows charts indicating the programmingcycles for both time controlled and count controlled operations. Part A of Figure 2 shows the programming cycle for time controlled operation in which the programming cycle consists of a trial count during which pulses from the sample under observation are scaled down by the Scaler and indicated as a Scaler output pulse for each thousand input pulses. The reset counter is time controlled during the trial count and the printing wheels of the print stamper are not connected to the timer motor so that a row of zeros is printed for each thousand pulses at the input of the Scaler. At the end of the predetermined time during which the count is to be taken the reset counter is reset and the complement period begins. The complement period continues until the scaler produces its next output pulse indicating that its last thousand input pulses has been completed. DuringV the complement period the print stamper is engaged to the timer motor and registers the time during which the complementing pulses are supplied to the Scaler.'

The program for count controlled operation with no` man. 0015. 02 }Sample Count is 2,000-(2067-1502)=1,435 in,

override timecontrol is shown in Figure 2B. During. the trial count the reset vcounter is count controlled and' the print stamper is connected to the timer motor so that.'

The programming cycle for count controlled operation' with override time control is shown in Figure 2C. This programming cycle consists of a trial count period, a complementing period and periods to allow for printing and resetting. During the trial count the time for eachv 1000 counts is printed as well as the time of the beginning,v

and end of the complementing period. The complementing period begins at the end of the predetermined time allowed by the override time control for a weak sample to occupy the apparatus and ends with the next output pulse from the sealer.v

The block diagram of a preferred embodiment of the` invention is shown in Figure 3. Several of the blocks shown in Figure 3 correspond to those shown in Figure 1 and are designated by the same reference numerals. As shown in Figure 3, a central base unit 41, in conjunction with a relay unit 42, is used to interconnect the other units whch, besides the units shown in Figure 1, include a time interval printer 43 of which the construction and operation will be described below.

The schematic Wiring diagrams for the base unit 41, including the reset counter 38, is shown in Figure 4. The base unit also includes a relay 1R which controls the operation of the reset counter 3S, a power on-oi switch S1, a switch S2, a manual-count control-time control switch S3, a start switch S4, a stop switch S5, and a reset switch S6. The base unit provides the necessary interconnections between the various units of the apparatus by means of socket connections designated as follows:

SM1-4o power mains,'

SM2-to register output of Scaler 32, SMS-to scaler control circuits, 1 SP4-to source 37 of regular timing pulses, SFS-to override time control 40, SPG-to time interval printer 35,

SF7, SFS and SF9-to relay unit 42, Y SFlt and SFl-to recycle unit 30, and SF 12-to complementer.

' In the designations for the sockets, the letter S indicates v Counter manufactured by the Eagle Signal Corporation of Moline, Illinois, U. S. A. K

A circuit for the source 37 of regular timing pulses` which is operative during time controlled operation of the apparatus is shown in Figure 5 and comprises an interlock relay 2R, a l0 R. P. M. synchronous motor driving a cam operated switch S7, and a plug connector FM4.v The designation FM4 for the plug connector indicates that it is a plug (P), male type (M), and the numeral (4) indicates that the plug connector is for connection to the socket SP4 (base unit, Figure 4). In operation, the cam operated switch S7 produces narrow time marker pulses spaced at 0.1 minute time intervals. The interlock relay 2R ensures that the trial starts at the. right instant in the time cycle; the predetermined time for the time com trolled operation being equivalent to an integral number of 'timing pulses. A

Figure 6 shows the circuit of thezoverridetime control 40 which may be a Cramer Tec-Timer, manufactured by R. W. Cramer Company, Centerbrook, Conn., U. S.

The override time control unit 40 has a plug connector PMS for 4connection to the base unit 41. The unit cornmences to time when the supply line is connected to its motor and, after the preselected period of time, it performs its switching functions. The unit is reset immediately the supply line to its motor is interrupted.

The standard printer unit 35 shown schematically in Figure 7 maybe a well known time interval printer such as the Traeergraph SC-5A time interval printer supplied by Tracerlab, Inc., 130 High Street, Boston l0, Mass., U. S. A., vor the type CPR time interval printer manufactured by Simplex Time Recorder Company, Gardner, Mass., U..S. A. The printer is arranged to be connected to the socket connector SF6 of the base unit 41 (Figures 3 and 4) by a plug connector PM6 which is connected to the circuits of the printer through connectors 5F13 and PM13, the purpose of which will be explained below in connectionwith Figure 1l. n The operation of the various printer controls is self evident from the circuit diagram. Y As shown resistors and capacitors supply spark suppression which avoids the possibility of the sealer or other equipment registering spurious counts due to sparks. Provision can be made for sample indexing if desired.

cam operated switches S8 to S12 inclusive. In operation, counting is started by the operation of the switch S10 and, while the trial is in progress, the motor is stopped by the action of the relay unit 42 (see Figures 3 and l0). On completion of the trial count the motor restarts and sequentially operates switch S11 (printsee Figure 2), S12 (reset printer and relay unit), and S9 (reset Scaler). The same motor may be used to drive the turntable of the sample changer, the switch S8 being connected to stop the motor in its correct cyclic condition for changing a sample manually, while the relay 10R and the switch S2 prolvide the necessary connections for reversing the turntab e.

The relay unit, shown schematically in Figure 10, is arranged to be connected to the base unit 41 (Figures 3 and 4) through male Yplug connectors PM7, PM8 and PM9,V and contains relays 3R, 4R, 5R, 6R, 7R and 8R and their associated interconnections. The sequence of operation and function of each of Vthe relays of the relay unit is tabulated in the following table. All the relays with the exception of relay 5R are A. Cooperated. Relay 5R derives D. C. power for `its operation from the sealer 32 (Figure 3).

TABLE 3 Counting Function Relay No. Contact Nos. Load Circuits (See Fig. 10)

Time Controlled Count Controlled 3R Energized at start ot trial. As in previous column,... Self maintaining.

De-energized by reset con- Conditions relay 4R. trol. Breaks start circuit.

Conditions print circuit. 4R Energized at end oi trial. Energlzed via relay R7 Starts sealer counting the complement. y De-energized by opening whenactuated by ovcr- Energizes relay QR (Fig. 8). 1

of relay SR. ride time control. Other- Energizes printer clutch (Time-com wise inoperative. trolled only). Opens supply to recycling motor. 5R Energized for 40 msecs. on Asinprevious column...- Releases relay SR on completing each Scaler output pulse. complement count and resets over- Y ride time control. Actuates print stampen 6R Energized at start of trial. As in previous column,... Stops recycling motor and energlzes De-energized at end of relay 3R. trial. Opens circuit to relay 4R.

Energizes relay 8B. Cczmplftrs print circuit to relay 5R 5 all 7B inoperative Euergized by operation of Energizcs relay 4R. K p override time control. Prints time when override control operates. Opens, rendering 5R (5 und 6) inoperative. De-energizes reset counter clutch. BR Energized during trial and As in previous colun1n Self maintaining.

complement periods. Start override tirnc control (countcontrolled only).

The eomplementer unit 33, as shown in Figure 8, comprises a 100 R. P. M. synchronous motor arranged to drive a slottedscanning disc to interrupt a light beam focused on the cathode of a photocell V1. The interrupted light beam produces a train of positive pulses in the anode circuit of a tube V2 and, after differentiation, these pulses trigger a gas triode V3 producing either positive or negative output pulses which can be selected by a switch SW1 depending on the requirements of the input circuit of the sealer 32 (Figure 3). Interchangeable scanning `dises for dierent pulse rates may be provided, for example discs having l, 6 or l0 slots for pulse rates of 100, 600 or'LOOO-per minute. The function of the relay 9R is to switch the connection to the sealer input (Figure 3) from the source of pulsesto be counted to the complementer. The external connections to the complementer Vare made through a plug connector PM12 which plugs into the socket connector 8F12 of the base unit (Figure 4). The recycling unit 30 which controls the sequence of operation of the various units (see Figure 2).-is shown f in VFigure 9. The recycling unit comprises a plug connector PM10 for connection to the socket connector SF10 ofthe base unit 41Y (Figures 3 and 4), a plug connector PM11 for Yconnection to the socket connector 8F11V of Y the bas`e"unit, a relay IGR, an On/Oi switch S1',`a switch S2 for reversing the turntable, and a series of motor driven V7) to record these elapsed times.

ln certain experiments, particularly the plotting of decay curves, it is necessary to record the centre time of each trial referred to some arbitrary time zero which is not necessarily the beginning of the counting operation. A separate unit as shown schematically in Figure ll can be used to control a second time interval printer (see Figure The control unit (Figure ll) comprises a reset counter, a relay 11R, an on/ o switch S1, a timer on/of switch S2, a start switch S3 and a stop-reset switch S4. The reset counter dial is set for one-half the setting ofthe reset counter in the base unit (Figure 4), and impulses for its count coil are derived from the relay 1R of Figure 4. Connection to the base Y unit (Figure 4) is made through the connectors PM16, 8F16 and PM6. The socket connector 8F13 provides the necessary connections to the trial count printer, and

the socket Vconnector 8F18 "provides the necessary connections to the elapsed time printer.

v'ihe method of operation in aV count controlled measurement'is as follows: (zero times being assumed to correspond with the vstart of theV rst trial).v When the first trial is started, the reset counter of the elapsed time control unit (Figure ll) is energized 'and in turn closes relay 11R which sets Vthe printer in motion. v- Half Away 9 time is printed. The reset counter remains de-energized until the start of the next trial. When the action isf repeated, the printer timing mechanismremaning lcontinuously engaged so that throughout the measurements the elapsed time for each trial is printed. The printer can be stopped and reset by pressing the switch S4. The

y10 switch S3 provides a means of setting the printer in motion at any convenient time prior to the beginning of the counting operations.

The operation of the various circuits shown in Figures 4 to 11 inclusive is shown graphically in Figure 12 and in the following tables (Tables 4, 5 and 6):

TABLE 4 Switching sequence for a time controlled trial with a sample changer COMPLETE CYCLE on OBSERVATION sTAm- TOTAL COUNT 1 A/c n/c l UNIT START Cousin- TRIAL (SAMPLE) coUNT --1-CQMPLEMENT lrRINT mism asser srm'r CYCLING sw; I1-s sn.- s-s slm se: lim UNIT Complement l2 Printer Scaler 2'3 Relay 3R Tntmzo ene -H s1: il: IMPULSE (Conditions 1P.) GENERA -lstoYTurntnhla on -1-2 (nu d) giil'ran md: 23am-Count con sums Time Mmm -s-I coun: LEGEND AN D Y Y Reset Reset-Counter Ile-Relay energized RELAY 1R fA-B Hold Rd--Relny deenergized Reset-Counter Clutch 3-4 Stan Releases 6R Contacts make-l-Z Count Contacts break-U2 l/Z Release 2R nhert ene: l-z; 7.a H-L f anni se sna: 1/2 p Commons 4R me; uur: 7-s 1 2 ma ws; s-e: ioni Cohtllliixlittled (Comit 0n) (Printer (Sltop (Restart (De-energia BRezl-Z: 9 Totalize Count) Motor) Rely Hold Open Start Line Complement) '--hle Energzed Every 1000: l-2 Prints- COMPLE- 9 Re Switch to Complement MENTER TABLE 5 Switching sequenceV for a count controlled trial with sample changer but without override time control COMPLETE CYCLE OF OPERATION AIC DIC UNIT S'IiART Y START TRIAL (SAMPLE) COUNT STOP PRTNT RESET RESET STAIRT CYCLING S10: 7-8 S11: 4-5 S12 S9: 11/12 UNIT Time for 1-2 Printer Scaler Preset Count 2/3 Relay 3R j TIMIN G 2Re -5-4 IMPULSE l vGIENERA.- n' TOR -5/6 (Stop Turntable) RESET lRd: 2-3 COUNTER LEGEND AND i RELAY 1R ["A-B Hold .Re-Relay energized Y Reset-Counter Clute -3-4 Start Count Rd-Relay 11e-energized L1/2 Release 2R Contacts make-1-2 Contacts break-U2 Count Coil Sums Scaler Output Until Preset Count Attained- Resets Reset-Counter A/B; 3/4 (Stop Count) Releases 6R RELAY Re: 1-2: 7-8 6Rd: 5-6

UNIT

Conditions 4Rd: 7/8 5-6: Print Circuit Stop Restart 3Re: 2: 8/9 Count Cycle Hold Open Start Line Motor 5R Energized Every 1000: 1-2 Prints Time Except When S2 Open Then Final Time Only Printed TABLE 6 l i Y HIMILETE CYCLE OF OPERATION i l A/c D/c l UNIT START STA RT TRIAL (SABIPLE) COUNT 1*- COMPLEMENT YIINT REISET RESIET STAIRT CYCLING S: T-8 S11: 4-5 S12 59111112 UNIT Tlme for Prel-2 Printer Scaler set Count or 2/3 Relay 3R Complement Y IIN H rMPULsn :Re l

NER R. 5/6(Stop'1urntubls) 1R11: -3 COUNTER VA-B Hold LEGEND AND RELAY Reset-Counter Ch tch-H Start Count 1R LN2 Release 2R' Re-Relny energized Y Rd- Relay decnerglzed v-Count Coll Sums Scaler Out t Until Preset Count Contacts make-l-2 Attuineil or Override Time ontrol perat In a Contacts breek-l/ Rcsnts Reset-Counter B; 3/4 (AS In Table 5 for Strong Sample: Rclenx 6R Weak Sample Complemento: 0p-

crate VRELAY 6R01 1-2: -S 4-5 Rd: 5-6 wir l a x Conditions additions 4R 1Ro: l-2: T-S (Print Time of Override) Print Circuit I Rez 10-11: 7-8 l-2 tEd: 7/8: 5-6. 10-11 Iet 1-2 8/9 Ro d Open Start Line Count O'n Prlnter Starts Eto? Restart De-en m Totalising Cou 1t Cycle Relay 9 #-511 Energlzed Every m10 Count: Complement Motor l-2 Prints Timo COMPLE- 9K0 Switch to Complement MENTEB In operation, the turntable of the recycle unit (Figures 3 and 9) has the samples to be measured arranged in a circle upon it in the usual manner so that, upon rotation of the turntable, each sample in turn comes directly beneath the Geiger counter. As soon as each sample is directly beneath the Geiger counter a cam operated hoist of well known construction lifts the sample to the window of the Geiger counter. lust as the sample comes to its rest position at the Geiger counter the switch S10 (Figure 9) closes, starting the count and stopping the turntable motor. Upon the count being completed, the turntable motor is started, the hoist lowered and the next sample is moved into position. During the time required Y to change samples, the result is printcdpand the counting mechanism is reset. Figure 122shows the state of energization of the various A. C. lines during operation of 'the equipment, and Tables 4, 5 and 6 indicate the/programming Vand point to point Vswitching throughout a cycle for time controlled and count controlled trials. Tables l and 2, referred to above in connection with Figure l, show examples of the printed records obtained.

A preferred construction of a time interval printer 35 (Figures 1 and 3) is shown in Figure 13. The preferred printer 35 comprises a synchronous motor (600 R. P. M.) coupled to four clutches, a count clutch C1, a reset count register clutch C2, a time clutch C3 and a reset time register clutch C4. The printer register drum is divided into three sections, an index register, a count Vregister in two parts-one numbered 0-99 for sealer output, pulse storage numbered 0-99, one numbered 999-0 for registering the complement, and a time register numbered 0-999.99 minutes or 09999.9 seconds depending on the gear ratios used. Separate printing mechanisms are provided for the count and time registers, the former also mentsl which are time controlledand have the elapsed Y centre time for each count printed. A spring loaded, Ypress to operate, switch S2 provides for remote control connecadvancing of the index register. Connections to the base tions for the operation of ythe index' register or .for manual 5 unit 41 (Figures 3 and 4) are made through a plug con-Y 7 nector PM6, and connections to the elapsed time control unit 43 (Figures 3 and l1) are made through a socket connector 8F16. When the printer shown in Figure 13 is used, the following modifications must be made in the circuits of the base unit (Figure 4) and the relay unit (Figure 10). In the base unit (Figure 4), section H of the switch S3, the connection to the count contact is broken and a connection is made between the count contact and the time contact. pins 8 and 9 of the socket SF6 are broken. In the relay unit (Figure 10), contacts 1 and 2 of relay 5R, break the connection to contact 1 and connect contact 1 to pin 1 of the plug PM9, and break the connection to contact 2 and connect contact 2 to pin 18 of the plug PM9. Using the printer shown 'in Figure 13 and assuming the predetermined scale of the Scaler is 1000:1 then, during timecontrolled operation, each count of 1000 is totalized in the storage register of the printer. At the same time the clutch of the time register is engaged (this feature is not essential) for the duration of the pre-set time interval. At the end of the pre-set time, the complementer operates and registers the residual sealer score by engaging the count clutch. Counting is then complete, the result is printed, the index advanced one, and the system is reset. In count-controlled operation, if the pre-set count is achieved within the time limit imposed by theoverride time control, then the complementer is not brought into operation. If the sample is weak, the override time .con-

trol will operate.` At the start of a sample count the time clutch is engaged, and each count of 1000 is totalized in the storage register until counting is complete whereupon the result is printed and the system reset. Time or countcontrolled sample counting can be carried out in'which a time record is provided of Yelapsed centre time (or any other suitable time) Vof each sample count as measured from some arbitrarily chosen zero time reference. In this case, each sample count is totalized on the count register, but the time clutch is continuously engagedand prints the time half way through each sample count and is never reset until the whole of theV counting operations have been carried out. Since the printing ofthe timeris half way through each sample'count, the time and count print irn-V pressions are made independently to avoid the necessity of double printing and so simplify the printed record.

The'following table (Table 7) shows examples of the count-time records obtainable with a printer Vas shown in Figure 13:

Also, the connections to the As shown in block form in Figure 14, automatic counting apparatus according to the present invention can be used in conjunction with a diierential channel 50 (which replaces the turntable) to provide an automatic pulse amplitude analyser (kicksorter). The analysing section of the apparatus may be of the well known type which When fed with random pulses of amplitude O to V classiiies them according to amplitude intervals of AV. The interval AV is known as the channel width, and the amplitude V contains N channels, where V N AV In the apparatus shown, only one differential channel 50 exists physically and it is made to assume the N levels sequentially. The pulse distribution is given by the time the channel S must remain at each level in order to sum a constant pulse total (count controlled operation); or alternately it may remain at each level for a fixed time (time controlled) and print the pulse totals. Override time control can be used with the count controlled method. 'Ihe recycle unit is, in general, the same as shown in Fig ure 9, and has a motor to operate the cam switches after each trial. A uniselector switch can be used to place the channel 50 at each of its levels and is analogous in action to the mechanical motion of a sample changing turntable. The relay R is omitted and an extra cam is added to actuate the uniselector at the end of each trial. Presentation of the results is the same as described above in connection with turntable operation.

What I claim as my invention is:

1. Apparatus for providing count or time control of a series of counting operations on trains of electrical pulses and for automatically recording the results, comprising a source of trains of electrical pulses, an electronic Scaler adapted to be connected to said source and to produce an output pulse for a number of input pulses in accordance with a predetermined scale, a source of regular timing pulses, a source of regular complementing pulses, a reset counter, a rst switch means controlled by the reset counter for connecting the scaler to the source of trains of electrical pulses and to the source of complementing pulses, a second switch means for connecting the reset counter to the scaler to count pulses from the scaler for count control of the counting operations and for connecting the reset counter to the source of timing pulses to count timing pulses for time control of the counting operations; the reset counter being adapted to operate the first switch means upon receiving a predetermined number of pulses to stop the sealer from being actuated by the trains of electrical pulses and to connect the source of complementing pulses to the scaler; a time interval printer having a print stamper and a timer motor for adjusting the setting of the print stamper to indicate elapsed time, the print stamper being connected to the sealer and adapted to be operated by an output pulse of the scaler and the timer motor being connected to the reset counter and adapted to be controlled by the reset counter to adjust the setting of the print stamper.

2. Apparatus as dened in claim 1, in which the second switch means connects the reset counter to the source of regular timing pulses and is adapted to disconnect the timer motor from the print stamper during the counting of a predetermined number of pulses by the reset counter and to connect the timer motor to the print stamper during the period complementing pulses are supplied to the scaler thereby to obtain a recorded measure of the time during which said complementing pulses are supplied 3. Apparatus as defined in claim 2 in which the print stamper of the time interval printer comprises two registers, the lrst of said registers being connected to the Scaler and adapted to be adjusted in setting by output pulses from the Scaler, and the second of said registers being connected to the timer motor through a clutch of which the period of engagement is controlled by pulses from the source of complementing pulses.

4. Apparatus as defined in claim 3 in which the second register is calibrated to provide readings in descending order from a number equal to the number of input pulses to the sealer which are required to produce an output pulse at the Scaler.

5. Apparatus as dened in claim l, in which the second switch means connects the reset counter to the Scaler, the timer motor of the time interval printer being connected to the print stamper, said apparatus comprising an override control adapted to determine the maximum time during which said electrical pulses can be supplied to the scaler and, upon said maximum time elapsing, to discontinue the supply of said electrical pulses to the scaler and to connect the source of complementing pulses to the sealer.

6. Apparatus as dened in claim 5 in which the print stamper of the time interval printer comprises three registers, the rst of said registers being connected to the scaler and adapted to be connected to output pulses from the Scaler, the second of said registers being adjusted in setting by the timer motor through a clutch of which the period of engagement is controlled by pulses from the source of complementing pulses, and the third of said registers being connected to the timer motor through a clutch which is engaged during the time for each counting operation, said second register being calibrated to provide readings in descending order from a number equal to the number of input pulses to the scaler which are required to produce an output pulse at the Scaler.

References Cited in the le of this patent UNITED STATES PATENTS Reeves Feb. 3, 1942 Bliss Aug. 28, 1951 OTHER REFERENCES 

